DENIERS SAY:

The idea that we’re warming the globe is debunked every time we have to bundle up and head outside to shovel away some climate change.

SCIENCE SAYS:

Global warming means there's less snow overall. But it could also bring more extreme snowstorms.

Any time there’s a big snowstorm, someone scoffs, “Global warming?! Yeah, right!” There are a few problems with that. First: It confuses a short-term, local event with the long-term trend that the planet is getting warmer. But here’s another fact that might surprise you. Even though the total amount of snow has declined in parts of the world over recent decades, there have been an increasing number of very heavy storms. That’s because a warmer climate increases evaporation, drawing moisture both from the oceans and the land. When that increased atmospheric moisture feeds into a storm, it can make the storm really, really big. The result: less snow overall as temperatures increase, but more extreme snowstorms.

Additional info from the Union of Concerned Scientists

For years, climate contrarians have pointed to snowfall and cold weather to question the scientific reality of human-induced climate change.

Their annual barrage of misinformation obscures the interesting work scientists are doing to figure out just how climate change is affecting weather patterns year-round.

What is the relationship between weather and climate?

Weather is what’s happening outside the door right now; today a snowstorm or a thunderstorm is approaching. Climate, on the other hand, is the pattern of weather measured over decades.

NASA and NOAA, plus research centers around the world, track the global average temperature, and all conclude that Earth is warming. In fact, the past decade has been found to be the hottest since scientists started recording reliable data in the 1880s. These rising temperatures are caused primarily by an increase of heat-trapping emissions in the atmosphere created when we burn coal, oil, and gas to generate electricity, drive our cars, and fuel our businesses. Hotter air around the globe causes more water evaporation, which fuels heavier precipitation in the form of more intense rain and snowstorms.

At the same time, because less of a region’s precipitation is falling in light storms and more of it in heavy storms, the risks of drought and wildfire are also greater. Ironically, higher air temperatures tend to produce intense drought periods punctuated by heavy floods, often in the same region.

These kinds of disasters may become a normal pattern in our everyday weather as levels of heat-trapping gases in the atmosphere continue to rise.

The United States is already experiencing more intense rain and snowstorms. The amount of rain or snow falling in the heaviest one percent of storms has risen nearly 20 percent averaged nationally — almost three times the rate of increase in total precipitation between 1958 and 2007.

Some regions of the country have seen as much as a 67 percent increase in the amount of rain or snow falling in the heaviest storms.

Overall, it’s warming, but we still have cold winter weather.

The seasons we experience are a result of the Earth’s tilted axis as it revolves around the sun. During the North American winter, our hemisphere is tilted away from the sun and its light hits us at a different angle, making temperatures lower.

While climate change won’t have any impact on Earth’s tilt, it is significantly shifting temperatures and causing spring weather to arrive earlier than it used to. Overall, spring weather arrives 10 days earlier than it used to, on average. “Spring creep" is something scientists projected would happen as the globe continues to warm.

The Arctic connection.

Winters have generally been warming faster than other seasons in the United States. However, recent research indicates that climate change is disrupting the Arctic and ice around the North Pole in a particularly interesting way. In the Arctic, frigid air is typically trapped in a tight loop known as the polar vortex. This super-chilled air is not only cold, it also tends to have low barometric pressure compared to the air outside the vortex. The surrounding high-pressure zones push in on the vortex from all sides so the cold air is essentially "fenced in" above the Arctic, where it belongs.

As the Arctic region warms faster than most other places, however, the Arctic sea ice melts more rapidly and for longer periods each year, and is unable to replenish itself in the briefer, warmer winter season. This can destabilize the polar vortex and raises the barometric pressure within it.

In two recent winter seasons (2009/2010 and 2010/2011), the polar vortex has been notably unstable. In addition, another measurement of barometric pressure — the North Atlantic Oscillation (NAO) — has been in negative mode, weakening part of the barometric pressure "fence" around the polar vortex. This instability allows the cold Arctic air to break free and flow southward, where it collides with warmer, moisture-laden air. This collision can produce severe winter weather.

The winter of 2009/2010 recorded the second-lowest negative phase of the NAO since the 1970s, which helps to explain the record snowfalls across the northeastern United States.

It’s not clear how much impact this trend will have in the future, especially as the Arctic ice continues to lose mass.